Branched, tripartite-interfering RNAs silence multiple target genes with long guide strands

Structural modifications could provide classical small interfering RNA (siRNA) structure with several advantages, including reduced off-target effects and increased silencing activity. Thus, RNA interference (RNAi)-triggering molecules with diverse structural modifications have been investigated by introducing variations on duplex length and overhang structure. However, most of siRNA structural variants are based on the linear duplex structure. In this study, we introduce a branched, non-linear tripartite-interfering RNA (tiRNA) structure that could induce silencing of multiple target genes. Surprisingly, the gene silencing by tiRNA structure does not require Dicer-mediated processing into smaller RNA units, and the 38-nt-long guide strands can trigger specific gene silencing through the RNAi machinery in mammalian cells. tiRNA also shows improved gene silencing potency over the classical siRNA structure when complexed with cationic delivery vehicles due to the enhanced intracellular delivery. These results demonstrate that tiRNA is a novel RNA nanostructure for executing multi-target gene silencing with increased potency, which could be utilized as a structural platform to develop efficient anticancer or antiviral RNAi therapeutics.     

siRNA抑制乙肝病毒的研究进展

乙型肝炎作为一种发病率高、死亡率高的传染性疾病,已严重威胁人类健康,乙肝病毒（hepatitis B virus,HBV）是诱发乙型肝炎的重要病因。目前,最主要的治疗方法是运用抗病毒药物控制病情,但这些药物都不能完全治愈乙型肝炎且复发率高。近年来,RNA干扰技术（RNA interference, RNAi）逐渐成为有效、快速治疗乙型肝炎的新疗法。利用RNA干扰技术体外合成针对HBV基因的siRNA,选择适当的载体将其运送至靶细胞,使HBV基因沉默,从而抑制病毒复制,可有效达到治疗乙肝的效果。本文围绕siRNA沉默HBV基因的设计原理、递送载体、靶向策略、以及治疗效果与应用前景等方面进行了系统综述,为今后siRNA治疗乙肝的临床应用提供参考。     

Photochemically induced gene silencing using small interfering RNA molecules in combination with lipid carriers

Novel strategies for efficient delivery of small interfering RNA (siRNA) molecules with a potential for targeting are required for development of RNA interference (RNAi) therapeutics. Here, we present a strategy that is based on delivery of siRNA molecules through the endocytic pathway, in order to develop a method for site-specific gene silencing. To achieve this, we combined the use of cationic lipids and photochemical internalization (PCI). Using the human S100A4 gene as a model system, we obtained potent gene silencing in four tested human cancer cell lines following PCI induction when using the cationic lipid jetSI-ENDO. Gene silencing was shown at both the RNA and protein levels, with no observed PCI toxicity when using the jetSI reagent and an optimized PCI protocol. This novel induction method opens for in vivo site-specific delivery of siRNA molecules toward a sequence of interest.     

Current progress of siRNA/shRNA therapeutics in clinical trials

Through a mechanism known as RNA interference (RNAi), small interfering RNA (siRNA) molecules can target complementary mRNA strands for degradation, thus specifically inhibiting gene expression. The ability of siRNAs to inhibit gene expression offers a mechanism that can be exploited for novel therapeutics. Indeed, over the past decade, at least 21 siRNA therapeutics have been developed for more than a dozen diseases, including various cancers, viruses, and genetic disorders. Like other biological drugs, RNAi-based therapeutics often require a delivery vehicle to transport them to the targeted cells. Thus, the clinical advancement of numerous siRNA drugs has relied on the development of siRNA carriers, including biodegradable nanoparticles, lipids, bacteria, and attenuated viruses. Most therapies permit systemic delivery of the siRNA drug, while others use ex vivo delivery by autologous cell therapy. Advancements in bioengineering and nanotechnology have led to improved control of delivery and release of some siRNA therapeutics. Likewise, progress in molecular biology has allowed for improved design of the siRNA molecules. Here, we provide an overview of siRNA therapeutics in clinical trials, including their clinical progress, the challenges they have encountered, and the future they hold in the treatment of human diseases.     

Clinical advances of siRNA therapeutics

Small interfering RNA (siRNA) enables efficient target gene silencing by employing a RNA interference (RNAi) mechanism, which can compromise gene expression and regulate gene activity by cleaving mRNA or repressing its translation. Twenty years after the discovery of RNAi in 1998, ONPATTRO? (patisiran) (Alnylam Pharmaceuticals, Inc.), a lipid formulated siRNA modality, was approved for the first time by United States Food and Drug Administration and the European Commission in 2018. With this milestone achievement, siRNA therapeutics will soar in the coming years. Here, we review the discovery and the mechanisms of RNAi, briefly describe the delivery technologies of siRNA, and summarize recent clinical advances of siRNA therapeutics.     

Kinesin spindle protein SiRNA slows tumor progression

The kinesin spindle protein (KSP), a member of the kinesin superfamily of microtubule‐based motors, plays a critical role in mitosis as it mediates centrosome separation and bipolar spindle assembly and maintenance. Inhibition of KSP function leads to cell cycle arrest at mitosis with the formation of monoastral microtubule arrays, and ultimately, to cell death. Several KSP inhibitors are currently being studied in clinical trials and provide new opportunities for the development of novel anticancer therapeutics. RNA interference (RNAi) may represent a powerful strategy to interfere with key molecular pathways involved in cancer. In this study, we have established an efficient method for intratumoral delivery of siRNA. We evaluated short interfering RNA (siRNA) duplexes targeting luciferase as surrogate marker or KSP sequence. To examine the potential feasibility of RNAi therapy, the siRNA was transfected into pre‐established lesions by means of intratumor electro‐transfer of RNA therapeutics (IERT). This technology allowed cell permeation of the nucleic acids and to efficiently knock down gene expression, albeit transiently. The KSP‐specific siRNA drastically reduced outgrowth of subcutaneous melanoma and ovarian cancer lesions. Our results show that intratumoral electro‐transfer of siRNA is feasible and KSP‐specific siRNA may provide a novel strategy for therapeutic intervention. J. Cell. Physiol. 228: 58–64, 2013. © 2012 Wiley Periodicals, Inc.     

Therapeutic aptamers: developmental potential as anticancer drugs

Aptamers, composed of single-stranded DNA or RNA oligonucleotides that interact with target molecules through a specific three-dimensional structure, are selected from pools of combinatorial oligonucleotide libraries. With their high specificity and affinity for target proteins, ease of synthesis and modification, and low immunogenicity and toxicity, aptamers are considered to be attractive molecules for development as anticancer therapeutics. Two aptamers - one targeting nucleolin and a second targeting CXCL12 - are currently undergoing clinical trials for treating cancer patients, and many more are under study. In this mini-review, we present the current clinical status of aptamers and aptamer-based cancer therapeutics. We also discuss advantages, limitations, and prospects for aptamers as cancer therapeutics. [BMB Reports 2015; 48(4): 234-237]     

New paradigms on siRNA local application

Small interfering RNA (siRNA) functions through pairing with specific mRNA sequences and results in the mRNA’s degradation. It is a potential therapeutic approach for many diseases caused by altered gene expression. The delivery of siRNA is still a major problem due to its rapid degradation in the circulation. Various strategies have been proposed to help with the cellular uptake of siRNA and short or small hairpin RNA (shRNA). Here, we reviewed recently published data regarding local applications of siRNA. Compared with systemic delivery methods, local delivery of siRNA/shRNA has many advantages, such as targeting the specific tissues or organs, mimicking a gene knockout effect, or developing certain diseases models. The eye, brain, and tumor tissues are ‘hot’ target tissues/organs for local siRNA delivery. The siRNA can be delivered locally, in naked form, with chemical modifications, or in formulations with viral or non-viral vectors, such as liposomes and nanoparticles. This review provides a comprehensive overview of RNAi local administration and potential future applications in clinical treatment. [BMB Reports 2015; 48(3): 147-152]     

综述: 适配子介导的siRNA转运

小分子干扰RNA(small interfering RNA,siRNA)因能快速抑制哺乳动物特定基因的表达而用于各种疾病的治疗,然而选择合适的载体将siRNA安全有效地转运进入靶细胞仍是制约siRNA应用于临床治疗的重要因素．越来越多的转运载体被开发出来,其中包括针对细胞表面蛋白的适配子(aptamer)．Aptamer是一种能与靶分子高特异性和高亲和结合的寡核苷酸,已经越来越多地用于疾病的诊断和治疗．Aptamer作为载体介导siRNA转运可提高治疗的靶向性并减少副作用,这将为siRNA应用于临床靶向治疗提供一种特异有效的途径．目前,已经发现几种aptamers可以介导siRNA的转运,如anti-PSMA aptamer,anti-HIV gp120 aptamer,anti-CD4 aptamer等．本文将综述aptamer介导siRNA转运的最新研究进展．     

针对SARS冠状病毒重要蛋白的siRNA设计(英)

RNA干涉(RNA interference, RNAi)是一种特异性地导致转录后基因沉默的现象,在哺乳动物细胞中小分子干扰RNA双链体(small interfering RNA duplexes, siRNA duplexes)可以有效地诱导RNAi现象,为一些疾病的治疗开辟了新的途径.针对SARS冠状病毒(SARS coronavirus, SARS-CoV)中编码5个主要蛋白质的基因,用生物信息学的方法设计了348条候选siRNA靶标.在理论上,相应的siRNA双链体能特异地抑制SARS-CoV靶基因的表达,同时不会影响人体细胞基因的正常表达,这为进一步siRNA类药物的实验研究提供了理论基础.     

Plasma exosomes can deliver exogenous short interfering RNA to monocytes and lymphocytes

Despite the promise of RNA interference (RNAi) and its potential, e.g. for use in cancer therapy, several technical obstacles must first be overcome. The major hurdle of RNAi-based therapeutics is to deliver nucleic acids across the cell's plasma membrane. This study demonstrates that exosome vesicles derived from humans can deliver short interfering RNA (siRNA) to human mononuclear blood cells. Exosomes are nano-sized vesicles of endocytic origin that are involved in cell-to-cell communication, i.e. antigen presentation, tolerance development and shuttle RNA (mainly mRNA and microRNA). Having tested different strategies, an optimized method (electroporation) was used to introduce siRNA into human exosomes of various origins. Plasma exosomes (exosomes from peripheral blood) were used as gene delivery vector (GDV) to transport exogenous siRNA to human blood cells. The vesicles effectively delivered the administered siRNA into monocytes and lymphocytes, causing selective gene silencing of mitogen-activated protein kinase 1. These data suggest that human exosomes can be used as a GDV to provide cells with heterologous nucleic acids such as therapeutic siRNAs.     

Quantitative evaluation of siRNA delivery in vivo

Effective small interfering RNA (siRNA)-mediated therapeutics require the siRNA to be delivered into the cellular RNA-induced silencing complex (RISC). Quantitative information of this essential delivery step is currently inferred from the efficacy of gene silencing and siRNA uptake in the tissue. Here we report an approach to directly quantify siRNA in the RISC in rodents and monkey. This is achieved by specific immunoprecipitation of the RISC from tissue lysates and quantification of small RNAs in the immunoprecipitates by stem-loop PCR. The method, expected to be independent of delivery vehicle and target, is label-free, and the throughput is acceptable for preclinical animal studies. We characterized a lipid-formulated siRNA by integrating these approaches and obtained a quantitative perspective on siRNA tissue accumulation, RISC loading, and gene silencing. The described methodologies have utility for the study of silencing mechanism, the development of siRNA therapeutics, and clinical trial design.     

针对SARS冠状病毒重要蛋白的siRNA设计(英文)

NA干涉 (RNAinterference ,RNAi)是一种特异性地导致转录后基因沉默的现象 ,在哺乳动物细胞中小分子干扰RNA双链体 (smallinterferingRNAduplexes ,siRNAduplexes)可以有效地诱导RNAi现象 ,为一些疾病的治疗开辟了新的途径 .针对SARS冠状病毒 (SARScoronavirus ,SARS CoV)中编码 5个主要蛋白质的基因 ,用生物信息学的方法设计了3 48条候选siRNA靶标 .在理论上 ,相应的siRNA双链体能特异地抑制SARS CoV靶基因的表达 ,同时不会影响人体细胞基因的正常表达 ,这为进一步siRNA类药物的实验研究提供了理论基础     

RNA干涉及其应用前景

RNA干涉是指由特定双链RNA(dsRNA)引起的转录后基因沉默现象。研究表明,Dicer断裂dsRNA产生的小干涉RNA可以抑制哺乳动物体细胞和胚胎中的基因的表达。RdRP在扩增RNAi中起着关键性的作用,RdRP活性复制较长的触发性dsRNA或以一种非引物的方式复制短的siRNA,即以siRNA为引物的RdRP反应使靶mRNA转变为dsRNA,同时复制触发性dsRNA。所有的产物又可作为Dicer的底物,起始RdRP级联反应。本文综述了RNAi可能的作用机制,并对RNAi在分析功能基因组、药物治疗等方面的应用前景进行了展望。     

Glucan particles for selective delivery of siRNA to phagocytic cells in mice

Phagocytic macrophages and dendritic cells are desirable targets for potential RNAi (RNA interference) therapeutics because they often mediate pathogenic inflammation and autoimmune responses. We recently engineered a complex 5 component glucan-based encapsulation system for siRNA (small interfering RNA) delivery to phagocytes. In experiments designed to simplify this original formulation, we discovered that the amphipathic peptide Endo-Porter forms stable nanocomplexes with siRNA that can mediate potent gene silencing in multiple cell types. In order to restrict such gene silencing to phagocytes, a method was developed to entrap siRNA-Endo-Porter complexes in glucan shells of 2-4 μm diameter in the absence of other components. The resulting glucan particles containing fluorescently labelled siRNA were readily internalized by macrophages, but not other cell types, and released the labelled siRNA into the macrophage cytoplasm. Intraperitoneal administration of such glucan particles containing siRNA-Endo-Porter complexes to mice caused gene silencing specifically in macrophages that internalized the particles. These results from the present study indicate that specific targeting to phagocytes is mediated by the glucan, whereas Endo-Porter peptide serves both to anchor siRNA within glucan particles and to catalyse escape of siRNA from phagosomes. Thus we have developed a simplified siRNA delivery system that effectively and specifically targets phagocytes in culture or in intact mice.     

Cell-Penetrating Magnetic Nanoparticles for Highly Efficient Delivery and Intracellular Imaging of siRNA

RNA interference is one of the most promising technologies for cancer therapeutics, while the development of a safe and effective small interfering RNA (siRNA) delivery system is still challenging. Here, amphipol polymer and protamine peptide were employed to modify magnetic nanoparticles to form cell-penetrating magnetic nanoparticles (CPMNs). The unique CPMN could efficiently deliver the eGFP siRNA intracellularly and silence the eGFP expression in cancer cells, which was verified by fluorescent imaging of cancer cells. Compared with lipofectamine and polyethyleneimine (PEI), CPMNs showed superior silencing efficiency and biocompatibility with minimum siRNA concentration as 5 nm in serum-containing medium. CPMN was proved to be an efficient siRNA delivery system, which will have great potential in applications as a universal transmembrane carrier for intracellular gene delivery and simultaneous MRI imaging.     

Using siRNA in prophylactic and therapeutic regimens against SARS coronavirus in Rhesus macaque

Development of therapeutic agents for severe acute respiratory syndrome (SARS) viral infection using short interfering RNA (siRNA) inhibitors exemplifies a powerful new means to combat emerging infectious diseases. Potent siRNA inhibitors of SARS coronavirus (SCV) in vitro were further evaluated for efficacy and safety in a rhesus macaque (Macaca mulatta) SARS model using clinically viable delivery while comparing three dosing regimens. Observations of SARS-like symptoms, measurements of SCV RNA presence and lung histopathology and immunohistochemistry consistently showed siRNA-mediated anti-SARS efficacy by either prophylactic or therapeutic regimens. The siRNAs used provided relief from SCV infection-induced fever, diminished SCV viral levels and reduced acute diffuse alveoli damage. The 10-40 mg/kg accumulated dosages of siRNA did not show any sign of siRNA-induced toxicity. These results suggest that a clinical investigation is warranted and illustrate the prospects for siRNA to enable a massive reduction in development time for new targeted therapeutic agents.     

人工 microRNA 技术研究进展

RNA干扰（RNAi）是由双链RNA触发的在mRNA水平进行的特异靶序列的基因沉默现象,广泛存在于动物、植物和病毒中,主要包括小干扰RNA（siRNA）及微小RNA（miRNA）两种作用途径。人工miRNA（amiRNA）是将天然miRNA的成熟序列替换成人工设计的靶向其他感兴趣基因的反义序列,通过天然miRNA的生成和作用途径达到RNAi的效果,具有干扰效果明显、作用迅速、毒性低等优点,拥有广阔的应用前景。我们对基于amiRNA的基因沉默技术进行了较为系统的介绍和总结,梳理了该技术的优缺点和适用范围,并展望了其进一步发展的方向和应用前景。     

Comprehensive evaluation of canonical versus Dicer-substrate siRNA in vitro and in vivo

Since the discovery of RNA interference (RNAi), researchers have identified a variety of small interfering RNA (siRNA) structures that demonstrate the ability to silence gene expression through the classical RISC-mediated mechanism. One such structure, termed "Dicer-substrate siRNA" (dsiRNA), was proposed to have enhanced potency via RISC-mediated gene silencing, although a comprehensive comparison of canonical siRNAs and dsiRNAs remains to be described. The present study evaluates the in vitro and in vivo activities of siRNAs and dsiRNAs targeting Phosphatase and Tensin Homolog (PTEN) and Factor VII (FVII). More than 250 compounds representing both siRNA and dsiRNA structures were evaluated for silencing efficacy. Lead compounds were assessed for duration of silencing and other key parameters such as cytokine induction. We identified highly active compounds from both canonical siRNAs and 25/27 dsiRNAs. Lead compounds were comparable in potency both in vitro and in vivo as well as duration of silencing in vivo. Duplexes from both structural classes tolerated 2'-OMe chemical modifications well with respect to target silencing, although some modified dsiRNAs demonstrated reduced activity. On the other hand, dsiRNAs were more immunostimulatory as compared with the shorter siRNAs, both in vitro and in vivo. Because the dsiRNA structure does not confer any appreciable benefits in vitro or in vivo while demonstrating specific liabilities, further studies are required to support their applications in RNAi therapeutics.